	US 11,873,268 B2
	Process for the production of urea formaldehyde concentrate
Marcus Symreng, Malmö (SE); and Pat A. Han, Smørum (DK)
Assigned to Topsoe A/S, Kgs. Lyngby (DK)
Appl. No. 17/420,025
Filed by Haldor Topsøe A/S, Kgs. Lyngby (DK)
PCT Filed Mar. 5, 2020, PCT No. PCT/EP2020/055861 § 371(c)(1), (2) Date Jun. 30, 2021, PCT Pub. No. WO2020/187583, PCT Pub. Date Sep. 24, 2020.
Claims priority of application No. PA 2019 00321 (DK), filed on Mar. 15, 2019.
Prior Publication US 2022/0048853 A1, Feb. 17, 2022
Int. Cl. C07C 273/04 (2006.01); C07C 29/152 (2006.01); C07C 273/10 (2006.01); C07C 45/38 (2006.01); C07C 29/151 (2006.01); C01C 1/04 (2006.01); C01B 3/38 (2006.01); C01B 3/02 (2006.01)

CPC C07C 273/04 (2013.01) [C01B 3/025 (2013.01); C01B 3/382 (2013.01); C01C 1/0488 (2013.01); C07C 29/152 (2013.01); C07C 29/1518 (2013.01); C07C 45/38 (2013.01); C07C 273/10 (2013.01); C01B 2203/0233 (2013.01); C01B 2203/0244 (2013.01); C01B 2203/0288 (2013.01); C01B 2203/0415 (2013.01); C01B 2203/0445 (2013.01); C01B 2203/0475 (2013.01); C01B 2203/061 (2013.01); C01B 2203/068 (2013.01)]

3 Claims

1. A process for the production of a urea formaldehyde concentrate from a hydrocarbon feedstock comprising steps of:

(a) producing a synthesis gas containing hydrogen, carbon monoxide, carbon dioxide and nitrogen by steam reforming the hydrocarbon feedstock in a primary reforming stage and subsequently in a secondary reforming stage;

(b) splitting the synthesis gas from step (a) into a methanol synthesis gas and an ammonia synthesis gas;

(c) subjecting the ammonia synthesis gas from step (b) in series to a high temperature water gas shift and a low temperature water gas shift conversion;

(d) removing at least part of the carbon dioxide from the ammonia synthesis gas from step (c) to obtain a carbon dioxide depleted ammonia synthesis gas;

(e) subjecting the carbon dioxide depleted ammonia synthesis gas from step (d) to catalytic methanation to remove the unconverted carbon monoxide to obtain a purified ammonia synthesis gas;

(f) catalytically converting the nitrogen and hydrogen in the purified ammonia synthesis gas from step (e) in an ammonia synthesis stage and withdrawing an effluent containing ammonia;

(g) passing at least part of the ammonia containing effluent to a urea synthesis stage, converting the ammonia in the effluent to urea product by reaction with at least part of the carbon dioxide being removed from the synthesis gas in step (d), and preparing an aqueous urea solution from the urea product;

(h) catalytically converting the carbon monoxide, carbon dioxide and hydrogen of the methanol synthesis gas from step (b) in a once-through methanol synthesis stage and withdrawing an effluent containing methanol and an effluent containing nitrogen, hydrogen and unconverted carbon monoxide and carbon dioxide;

(i) recycling the effluent containing nitrogen, hydrogen and un-converted carbon monoxide and carbon dioxide: (i) to a fuel header as fuel to the primary reforming stage in step (a) and/or (ii) to the low temperature shift conversion in step (c);

(j) subjecting the effluent containing methanol to distillation and withdrawing purified methanol from the distillation;

(k) oxidizing at least a part of the purified methanol from step (j) to formaldehyde;

(l) absorbing the formaldehyde from step (k) in an absorber with water and the aqueous urea solution prepared from the urea product in step (g) to obtain the urea formaldehyde concentrate,

wherein the effluent containing nitrogen, hydrogen and unconverted carbon monoxide and carbon dioxide in step (i) is recycled to the low temperature shift conversion in step (c) with an ejector using main flow from the high temperature water gas shift as motive flow and the effluent as suction flow.